From Head First design patterns book, the singleton pattern with double checked locking has been implemented as below:

public class Singleton {
    private volatile static Singleton instance;
    private Singleton() {}
    public static Singleton getInstance() {
        if (instance == null) {
            synchronized (Singleton.class) {
                if (instance == null) {
                    instance = new Singleton();
        return instance;

I don't understand why volatile is being used. Doesn't volatile usage defeat the purpose of using double checked locking i.e performance?

  • 7
    I thought double checked locking was broken, did somebody fix it? Oct 21 '11 at 21:59
  • 4
    For what it's worth, I found Head First design patterns to be a horrible book to learn from. As I look back on it, it makes perfect sense now that I've learned the patterns elsewhere, but to learn without knowing the patterns it really did not serve it's purpose. But it's very popular, so perhaps it was just me being dense. :-)
    – corsiKa
    Oct 21 '11 at 21:59
  • @DavidHeffernan I have seen this example used as the one way in which the jvm can be trusted to do the DCL. Oct 21 '11 at 22:04
  • FWIW, on an x86 system a volatile Read-Read is supposed to result in a no-op. In fact, the only operation that requires a fence for memory consistency is a volatile Write-Read. So if you really only write the value once, then there should be minimal impact. I've not seen anyone actually benchmark this and think the result would be interesting!
    – Tim Bender
    Oct 21 '11 at 22:10
  • 1
    check this link for why volatile is used in singleton: cs.umd.edu/~pugh/java/memoryModel/DoubleCheckedLocking.html
    – Rajesh.k
    Mar 16 '21 at 12:16

A good resource for understanding why volatile is needed comes from the JCIP book. Wikipedia has a decent explanation of that material as well.

The real problem is that Thread A may assign a memory space for instance before it is finished constructing instance. Thread B will see that assignment and try to use it. This results in Thread B failing because it is using a partially constructed version of instance.

  • 1
    OK, it looks like a new implementation of volatile fixed the memory issues with DCL. What I still don't get is the performance implication of using volatile here. From what I have read volatile is pretty much as slow as synchronized so why not just synchronize the whole getInstance() method call?
    – toc777
    Oct 21 '11 at 22:39
  • 6
    @toc777 volatile is slower than a usual filed. If you look for performance, go for a holder-class pattern. volatile is here merely to show that there's a way to make the broken pattern work. It's more of a coding challenge than a real problem.
    – alf
    Oct 21 '11 at 22:43
  • 6
    @Tim well, a singleton in XML is still a singleton; understanding the runtime state of an app doesn't become easier by using DI. smaller units of code may seem simpler, at the expense of forcefully structuring all units to conform to DI idiom (a good thing some might say). The accusation against singleton is not fair, it confuses API with impl - Foo.getInstance() is just an expression to get a Foo somehow, it's no different from @Inject Foo foo; either way the site that requests a Foo is agnostic of which Foo is returned and how, either way static and runtime dependencies are the same. Oct 22 '11 at 3:18
  • 2
    @irreputable You know what is funny is that at the time we had this exchange, I had never used Spring and wasn't referring to Spring's wonky DI. The real danger with Singleton as a static factory is the temptation to call it deep inside code which should not know of the getInstance() method and instead demand an instance be provided.
    – Tim Bender
    Jun 8 '13 at 2:05
  • 2
    The real problem is that Thread A may assign a memory space for instance before it is finished constructing instance. So how volatile resolve this ?
    – shaoyihe
    Oct 31 '18 at 5:24

As quoted by @irreputable, volatile is not expensive. Even if it is expensive, consistency should be given priority over performance.

There is one more clean elegant way for Lazy Singletons.

public final class Singleton {
    private Singleton() {}
    public static Singleton getInstance() {
        return LazyHolder.INSTANCE;
    private static class LazyHolder {
        private static final Singleton INSTANCE = new Singleton();

Source article : Initialization-on-demand_holder_idiom from wikipedia

In software engineering, the Initialization on Demand Holder (design pattern) idiom is a lazy-loaded singleton. In all versions of Java, the idiom enables a safe, highly concurrent lazy initialization with good performance

Since the class does not have any static variables to initialize, the initialization completes trivially.

The static class definition LazyHolder within it is not initialized until the JVM determines that LazyHolder must be executed.

The static class LazyHolder is only executed when the static method getInstance is invoked on the class Singleton, and the first time this happens the JVM will load and initialize the LazyHolder class.

This solution is thread-safe without requiring special language constructs (i.e. volatile or synchronized).


Well, there's no double-checked locking for performance. It is a broken pattern.

Leaving emotions aside, volatile is here because without it by the time second thread passes instance == null, first thread might not construct new Singleton() yet: no one promises that creation of the object happens-before assignment to instance for any thread but the one actually creating the object.

volatile in turn establishes happens-before relation between reads and writes, and fixes the broken pattern.

If you are looking for performance, use holder inner static class instead.

  • 1
    hi @alf,According to happens-before definition, after one thread releases the lock, another thread acquires the lock, then the latter can see the previous change. If so, I don't think the volatile keyword is needed . Can you explain it in more detail Jul 5 '18 at 2:21
  • But there's no lock acquisition in the case the second thread only hits the outer if, so no ordering.
    – alf
    Jul 5 '18 at 8:47
  • Hi @alf, So are you trying to state that when the first thread creates the instance inside synchronized block then that instance might still be null to the second thread bec of cache misses and it instances it again if the instance is not volatile? can you please clarify ? Jul 26 '20 at 14:57
  • 2
    @AarishRamesh, not null; any state whatsoever. there are two operations: assigning address to the instance variable, and the actual creation of the object at that address. Unless there's something enforcing synchronisation, like a volatile access or an explicit syncronization, the second thread can get those two events out of order.
    – alf
    Jul 27 '20 at 15:55

Declaring the variable as volatile guarantees that all accesses to it actually read its current value from memory.

Without volatile, the compiler may optimize away the memory accesses to the variable (such as keeping its value in a register), so only the first use of the variable reads the actual memory location holding the variable. This is a problem if the variable is modified by another thread between the first and second access; the first thread has only a copy of the first (pre-modified) value, so the second if statement tests a stale copy of the variable's value.

  • 4
    -1 I'm losing my reputation points today :) The real reason is, there's memory cache, modeled as thread's local memory. The order in which local memory is flushed to the main one is undefined—that is, unless you have happens-before relations, e.g., by using volatile. Registers have nothing to do with incomplete objects and DCL problem.
    – alf
    Oct 21 '11 at 22:14
  • 3
    Your definition of volatile is too narrow - if that was all volatile did, double checked locking would've worked just fine in <Java5. volatile introduces a memory barrier making certain reordering illegal - without that even if we never read stale values from memory it'd still be unsafe. Edit: alf beat me to it, shouldn't have gotten myself some nice tea ;)
    – Voo
    Oct 21 '11 at 22:18
  • 1
    @TimBender if singleton contains mutable state, flushing it has nothing to do with a reference to the singleton itself (well, there's an indirect link, as accessing a volatlie reference to a singleton makes your thread re-read main memory—but it's a secondary effect, not the cause of a problem:))
    – alf
    Oct 21 '11 at 22:18
  • @alf, you're right. And actually making instance volatile doesn't help if the state inside is mutable since the flush only happens if the reference itself is changed (like making arrays/lists volatile does nothing for the contents). Chalk it up to a brain fart.
    – Tim Bender
    Oct 21 '11 at 22:22
  • According to happens-before definition, after one thread releases the lock, another thread acquires the lock, then the latter can see the previous change. If so, I don't think the volatile keyword is needed . Can you explain it in more detail @Tim Bender Jul 5 '18 at 2:35

If you didn't have it, a second thread could get into the synchronized block after the first set it to null, and your local cache would still think it was null.

The first one is not for correctness (if it were you are correct that it would be self defeating) but rather for optimization.

  • 1
    According to happens-before definition, after one thread releases the lock, another thread acquires the lock, then the latter can see the previous change. If so, I don't think the volatile keyword is needed . Can you explain it in more detail Jul 5 '18 at 2:32
  • @QinDongLiang If the variable is not volatile, the second thread may be using a cached value on its own stack. Being volatile forces it to go back to the source to get the proper value. Of course, it has to do this on every access and thus can have a performance hit (but let's be honest, unless it's in a super critical loop, it's probably not the worst thing in your system...)
    – corsiKa
    Jul 5 '18 at 3:43

A volatile read is not really expensive in itself.

You can design a test to call getInstance() in a tight loop, to observe the impact of a volatile read; however that test is not realistic; in such situation, programmer usually would call getInstance() once and cache the instance for the duration of use.

Another impl is by using a final field (see wikipedia). This requires an additional read, which may become more expensive than the volatile version. The final version may be faster in a tight loop, however that test is moot as previously argued.


Double checked locking is a technique to prevent creating another instance of singleton when call to getInstance method is made in multithreading environment.

Pay attention

  • Singleton instance is checked twice before initialization.
  • Synchronized critical section is used only after first checking singleton instance for that reason to improve performance.
  • volatile keyword on the declaration of the instance member. This will tell the compiler to always read from, and write to, main memory and not the CPU cache. With volatile variable guaranteeing happens-before relationship, all the write will happen before any read of instance variable.


  • Since it requires the volatile keyword to work properly, it's not compatible with Java 1.4 and lower versions. The problem is that an out-of-order write may allow the instance reference to be returned before the singleton constructor is executed.
  • Performance issue because of decline cache for volatile variable.
  • Singleton instance is checked two times before initialization.
  • It's quite verbose and it makes the code difficult to read.

There are several realization of singleton pattern each one with advantages and disadvantages.

  • Eager loading singleton
  • Double-checked locking singleton
  • Initialization-on-demand holder idiom
  • The enum based singleton

Detailed description each of them is too verbose so I just put a link to a good article - All you want to know about Singleton

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